KR101557662B1 - Fossil footprints excavating method - Google Patents

Abstract

The present invention relates to a fossil footprint excavating method. A target area to be excavated is set, a work space is secured by cutting out surrounding areas of the target area, a peripheral area is covered and pulled to be cut out using a wire saw, supporters are inserted into the lower part of the target area, steel support members are installed in the space formed by the supporters, thereby forming a frame based on the support members. As such, an excavated ground can be transferred to an exhibition or the like while maintaining its original shape as much as possible. Accordingly, damage to a fossil footprint can be prevented, thereby increasing the academic value of the fossil footprint and maximizing the effect of the study and exhibit.

Description

{Fossil footprints excavating method}

The present invention relates to a method of discovery of footprint fossils such as dinosaurs, pterosaurs, new footprints, and the like using a wire saw and a frame to conveniently transport fossils containing rocks around the fossil It is about the fossil discovery method.

There are many ways to find common fossils.

Specifically, a stereoscopic (three-dimensional) fossil with an actual substance like a dinosaur bone finds a stratum containing fossils, carries out fossilization, fills the fossil with a gypsum, removes the gypsum, removes the rock around the skeleton We use a method to display the fossil bone in the back bone.

On the other hand, footprint fossils of the same shape as the land formed by pressing on the ground are generally made up of solid rock masses, so the footprints fol- lowed by dinosaurs There are many necessities to be wide and long.

However, in applying the latter method, small and narrow footprint fossils generally can be cut in small size, but in order to preserve them, large footprint fossils are distributed in a large and wide range of footprint fossils and excavated areas When the excavation and transportation are difficult, there are difficulties in excavation and transportation, and the excavation is abandoned or cut into several irregular pieces, transported, reassembled and exhibited.

However, such a method has been unable to exhibit complete footprint fossils even after reassembling, such as a lot of damage to a footprint fossil specimen during reassembling and reassembling into irregular pieces. In this way, the fossilized footprints are damaged, which reduces the value of academic preservation. In the process of reassembling, when many cracks occur in the rocks due to work errors or the like, they are damaged to such an extent that they can not be exhibited.

Techniques related to footprint fossil discovery include "The first mechanical work in Korea to find dinosaur footprints (Busan Ilbo, Nov. 14, 2007)" is disclosed. This method is to apply a wire cow as a method to separate the upper rock bed containing the footprint fossils from the lower rock bed to excavate dinosaur footprint fossils. However, it has been difficult to propose a safe and convenient method for transporting rocks by separating upper and lower rocks using wire cow.

There is a technique related to solving such a problem, for example, a " method for recovering a transfer structure for transferring a transfer material and a transfer method for transferring a transfer material using the same, " (Patent Document No. 10-1143254, Patent Document 1). This is a technology to transfer and restore the preserved molds in the soil layer.

However, the above-mentioned Patent Document 1 differs in the tools and equipments used for the work process and the work because the former is located in the soft soil rather than the hard rock, There is a problem that the water is transported while being damaged.

KR 10-1143254 (April 29, 2012)

The footprint fossil discovery method of the present invention is intended to solve the problems occurring in the conventional art as described above, and it is not necessary to separate a large footprint fossil or a rock bed or fossil bed including a fossil group into several pieces, To prevent damage to fossils, to increase academic value, and to maximize the effects of research and exhibition.

Especially, it is aimed to minimize the occurrence of cracks or breakage in the excavation part during the cutting process by minimizing vibration and impact at the excavation part to be conveyed through the incision using the wire saw.

In addition, in the cutting process using a wire saw, a supporting member is fitted to the lower portion of the excavating portion, a vertical member is connected to the upper portion thereof, and a connecting member is connected to form a frame that surrounds the excavating portion. So that the load of the excavation part is uniformly dispersed during the transportation process, thereby minimizing occurrence of cracks and breakage in transportation and transportation.

In addition, the nonwoven fabric and the waterproof vinyl are covered each time the step of cutting the bottom of the surrounding rock to form the work space and the bottom of the excavation end are finished, and the metal is bent in the horizontal and vertical directions by the banding member, To prevent the cracks or broken pieces that are generated from falling off the surface of the excavation part.

Further, by providing an auxiliary support member in a direction intersecting with the support member after frame formation, the support member is prevented from sagging due to the excavation load.

In addition, the flow preventive member is closely attached to the sidewall surface of the excavation portion to minimize the damage by preventing the flow of the excavation portion during traction and transportation.

The footprint fossil discovery method of the present invention includes a sedimentary rock removal step of removing an upper sedimentary rock 30 of a fossil finder 20 in which a footprint fossil 10 is found; Determining a digging unit (40) by examining a distribution of footprint fossils on a detection site (20) from which the sedimentary rock (30) is removed; The nonwoven fabric 41 is covered on the surface of the excavating portion 40 and then the surrounding rock is cut and crushed using the diamond saw to form the working space 50 around the excavating portion 40. In the excavating portion 40, The side working space 50 has a length corresponding to the width of the excavating portion 40; The nonwoven fabric 42 and the waterproofing vinyl 43 are sequentially covered from the upper part and the side surface of the excavating part 40 and then horizontally bent and bent by the metal bending member 44 in the horizontal direction Wow; A plurality of struts 71 are separated from each other at a lower portion of the excavated portion 40 that has been cut along with the cutting while cutting the lower end portion of the excavating portion 40 using the wire saw 60 And the steel supporting member 70 is inserted between the struts 71 to support the lower portion of the excavating portion 40 so that both side ends of the supporting member 70 protrude outward from the excavating portion 40, A supporting member inserting step; A vertical bending step of wrapping the surface of the digging unit 40 with a nonwoven fabric 45 and a waterproofing vinyl 46 and then bending the digging unit 40 in a vertical direction with a metal banding member 47; A vertical member 92 is connected to the upper portion of the lower connecting member 91 after the lower connecting member 91 connecting the end portions of the supporting members 70 is installed in a direction crossing the supporting member 70 A frame forming step of forming a frame 90 by providing an upper connecting member 93 connecting upper ends of the vertical members 92; A frame reinforcing step of pulling up the frame 90 in an upward direction and then tilting it to one side and connecting a plurality of auxiliary supporting members 100 in a direction intersecting with the supporting member 70; And a transfer step of transferring the frame (90).

In this case, after the frame reinforcing step, the inclined frame 90 is placed in parallel with the ground so that the excavating part 40 is positioned at the center of the frame 90, and then the supporting members 70 at both ends are connected, And a flow preventive step of additionally providing a flow preventive member (80) made of a steel, the one side of which is brought into close contact with the digging part (40) to prevent the flow of the frame (90).

According to the present invention, it is possible to prevent a footprint fossil from being damaged by transferring a large footprint fossil or a fossil group-containing rock bed or a stratum layer to a storage room or exhibition hall without cutting it into several pieces, , And maximize the effects of education.

Particularly, it is possible to minimize vibrations and impacts at the excavation part to be conveyed through the incision using the wire saw, thereby minimizing the occurrence of cracks or breakage in the excavation part during the cutting process.

In addition, in the cutting process using a wire saw, a supporting member is fitted to the lower portion of the excavating portion, a vertical member is connected to the upper portion thereof, and a connecting member is connected to form a frame that surrounds the excavating portion. The load of the excavating portion is evenly dispersed during the conveying process, so that occurrence of cracks and breakage in the conveying and conveying process can be minimized.

In addition, the nonwoven fabric and the waterproof vinyl are covered each time the step of cutting the bottom of the surrounding rock to form the work space and the bottom of the excavation end are finished, and the metal is bent in the horizontal and vertical directions by the banding member, It is possible to prevent the generated cracks or broken pieces from falling off the surface of the excavating portion.

Further, by providing the auxiliary support member in the direction intersecting the support member after frame formation, deflection of the support member due to the excavation part load can be prevented.

In addition, by providing the flow preventing member in close contact with the sidewall surface of the excavating portion, it is possible to minimize the damage by preventing the flow of the excavating portion during traction and transportation.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing an example of a footprint fossil spot before a sedimentary rock removal step in the present invention. FIG.
FIG. 2 is a perspective view showing a state in which a sedimentary rock removal step is performed in the present invention. FIG.
3 is a perspective view showing a state in which the excavated part is confirmed and marked by the excavation part confirmation step in the present invention.
4 is a perspective view showing a state in which a working space is formed around the excavation portion by the surrounding rock crushing step.
5 is a perspective view illustrating a state in which a horizontal bending step is performed in the present invention.
6 is a perspective view showing a step of cutting and inserting support members in the present invention.
7 is a perspective view showing a state in which the cutting and supporting member inserting step is completed in the present invention.
8 is a perspective view illustrating a state in which the vertical bending step is advanced in the present invention.
9 is a perspective view showing a frame forming step in the present invention.
10 is a perspective view showing a frame reinforcing step in the present invention.
11 is a perspective view showing a state in which a flow prevention step is performed in the present invention.

Hereinafter, a footprint fossil discovery method of the present invention will be described in detail with reference to the accompanying drawings.

1. Removal of sedimentary rocks

The upper sedimentary rock 30 of the fossil finder 20 where the footprint fossils 10 are found is removed.

FIG. 1 is a perspective view showing an example of a footprint fossil finder 20 before a sedimentary rock removal step according to the present invention. When a fossil 10 is found in a state where only some sedimentary rocks are removed, Likewise, the sedimentary rock 30 above the footprint fossil finder 20 is removed.

At this time, sedimentary rocks can be removed using equipment such as forklrains and manpower.

2. Determination phase of excavation department

The discovery site 20 from which the sedimentary rock 30 has been removed is examined for the distribution of the footprint fossils and the digging unit 40 is confirmed.

It is preferable that the determined digging unit 40 performs a marking process on the perimeter thereof by using a marking means such as a pen as shown in Fig.

After the determination of the excavation unit 40 and aerial photographing and 3D scanning are performed before and after the operation, asterix is applied on the footprint fossil 10 on the surface of the digging unit 40, You can draw shapes with a pen.

In addition, in order to prepare for damage during the excavation process, it is also possible to selectively select important footprint fossil specimens and produce replicas using alginate, gypsum, latex, silicone, and the like.

3. Step of crushing surrounding rock

The nonwoven fabric 41 is covered on the surface of the excavating portion 40 and then the surrounding rock is cut and crushed using the diamond saw to form the working space 50 around the excavating portion 40. In the excavating portion 40, The side working space 50 has a length corresponding to the width of the digging unit 40 in order to secure a space for inserting the supporting member.

More specifically, as shown in FIG. 4, in order to proceed with the cutting and supporting member inserting step to be described later, the outer diameter of the digging portion 40 is 30 to 100 cm in width and 20 to 50 cm in height, The rock is cut and crushed to form a work space 50 around the excavation unit 40. [

The reason for not using the known cutter or crusher is to minimize the occurrence of cracks in the excavating portion 40 due to vibration generated in the cutting process.

The cutting using the circular diamond saw is vertically cut at the boundary of the excavation portion 40, and cut away vertically from the outer portion of the excavation portion 40, and then the rock between the cut portions is removed by using a tablet or an excavator.

At this time, in order to secure a space in which the support member 70 can be inserted when the work space 50 is formed, on one side of the digging unit 40, It is indispensable to assure that the battery 50 is provided.

It is preferable that the surface of the non-woven fabric 41 is covered with the top of the digging section 40 prior to cutting.

4. Horizontal Bending Step

The nonwoven fabric 42 and the waterproofing vinyl 43 are sequentially covered from the upper portion and the side surface of the excavating portion 40 and then the side surface of the excavating portion 40 is covered with the metal bending member 44 Direction.

When the digging unit 40 is covered with the nonwoven fabric 42 and the waterproofing vinyl 43 and then bent and bent in the horizontal direction by the metal banding member 44, the fossil is protected after cutting and crushing, It is possible to prevent the cracks from being separated or damaged.

5. Cutting and Insertion of Supporting Member

After the wire rod 60 is prepared, the wire rod 60 is wrapped around the lower end of the rod 40 as shown in FIG. 6, and then pulled gradually from the lower end of one side of the rod 40.

At this time, a plurality of struts 71 are inserted into the lower part of the excavating part 40 cut at the same time as cutting.

In addition, the steel supporting member 70 is inserted between the strands 71 during cutting or after cutting to support the lower portion of the digging unit 40.

The state where the cutting and supporting member 70 is completely inserted is the same as that shown in FIG. 7, and both side ends of the supporting member 70 protrude outward from the digging unit 40 as shown in FIG.

The steel material supporting member 70 can be variously applied according to the load of the digging unit such as the H-shaped pipe.

The cutting using the wire saw can minimize the vibration as compared with other general cutting methods, and it is possible to prevent cracks or cracks on the surface of the digging unit 40 as much as possible.

6. Vertical Bending Step

The surface of the digging unit 40 is wrapped with the nonwoven fabric 45 and the waterproofing vinyl 46 as shown in FIG. 8, and the digging unit 40 is bent and surrounded by the metal banding member 47 in the vertical direction .

Bending once again vertically causes the underside of the excavating portion 40 to be separated from the rock, and the load is supported by the spaced apart support members 70, and the portion is not supported by the support member 70 The load is burdened and cracks are generated in the underside of the excavating part 40 or the pieces of the rock are separated from each other when a crack is generated in the cutting process through the wire saw.

In other words, the nonwoven fabric 45 and the waterproofing vinyl 46 prevent the deviation of the rock mass and prevent moisture infiltration. The banding with the banding member 47 is advantageous in that, even in the event of a small impact, I would say that it is to prevent me.

If there is a crack on the surface of the digging unit 40 before the horizontal bending step or the vertical bending step, an adhesive may be applied to reinforce cracks.

7. Frame formation step

9, a lower connecting member 91 for connecting ends of the supporting members 70 in a direction intersecting the supporting member 70 is provided, The frame 90 is formed by providing the upper connecting member 93 connecting the upper ends of the vertical members 92 after the connecting members 92 are connected.

9, there are provided two lower connecting members 91 for connecting the opposite ends of the supporting member 70 arranged side by side, and each of the lower connecting members 91 is connected vertically to the vertical members 92 .

In addition, an upper connecting member 93 connecting upper ends of the vertical members 92 is shown.

It is apparent that an unrepresented steel material connecting the ends of each of the lower connecting members 91 and the upper connecting member 93 is provided.

At this time, the connection between the members can be assembled and connected by various methods such as bolting method and welding.

8. Frame reinforcement step

10, the frame 90 is pulled upward and then tilted to one side, and then a plurality of auxiliary supporting members 100 are connected and installed in a direction intersecting with the supporting member 70. As shown in FIG.

The provision of the auxiliary support member 100 is intended to prevent occurrence of sagging of the support members 70 due to the load of the digging unit 40 which is a rock.

In particular, the auxiliary supporting member is connected to the supporting member 70, in particular, when the welding operation is performed, the frame is tilted so as to work in an empty space so as to be separated from the digging unit 40 and the non- .

In this case, after the frame reinforcing step, the inclined frame 90 is placed in parallel with the ground so that the excavating part 40 is positioned at the center of the frame 90, and then the supporting members 70 at both ends are connected, A flow preventing step of additionally providing a flow preventive member 80 made of a steel which is in close contact with the wall surface of the digging part 40 so as to prevent the flow of the excavating part 40 is further provided.

When the flow preventing member 80 is installed, the flow of the excavating portion 40 on the frame 90 is prevented, and the surface of the excavating portion 40 is prevented from being broken due to the shaking or impact generated when the flow preventing member 80 is moved.

FIG. 11 shows a state in which the frame 90 is inclined after proceeding to the flow prevention step, showing that the excavating portion 40 does not flow.

9. Transfer stage

The frame 90 is transported to a destination using a crane or the like.

According to the footprint fossil discovery method of the present invention as described above, the entire fossil to be excavated can be excavated as a single plate without any disassembly work.

In addition, the use of wires, the use of non-woven fabric and waterproofing vinyl, and the banding work are combined to minimize damage and loss of fossils that may occur during the disassembly process.

This minimizes discovery costs by saving manpower, equipment, and time used for dismantling.

In addition, when storing the excavated fossils, since the frames are already built, they can be stacked to minimize the storage space, and when restoration and exhibition work is carried out, there is no need to reassemble the disassembled fossil specimens one by one It is possible to dispose only the upper part and the side part of the frame after selecting an appropriate position, thereby simplifying installation.

10: Fossil 20: Found.
30: Sedimentary rock 40: Excavation site
41, 42, 45: Nonwoven fabric
43, 46: waterproof vinyl
44, 47: a bending member
50: work space 60: wire small
70: support member 71: strut
80: flow preventing member 90: frame
91: lower connecting member 92: vertical member
93: upper connecting member 100: auxiliary supporting member

Claims (2)

In a footprint fossil discovery method,
A sedimentary rock removing step of removing the upper sedimentary rock 30 of the fossil finder 20 where the footprint fossil 10 is found;
Determining a digging unit (40) by examining a distribution of footprint fossils on a detection site (20) from which the sedimentary rock (30) is removed;
The nonwoven fabric 41 is covered on the surface of the excavating portion 40 and then the surrounding rock is cut and crushed using the diamond saw to form the working space 50 around the excavating portion 40. In the excavating portion 40, The side working space 50 has a length corresponding to the width of the excavating portion 40;
The nonwoven fabric 42 and the waterproofing vinyl 43 are sequentially covered from the upper part and the side surface of the excavating part 40 and then horizontally bent and bent by the metal bending member 44 in the horizontal direction Wow;
A plurality of struts 71 are separated from each other at a lower portion of the excavated portion 40 that has been cut along with the cutting while cutting the lower end portion of the excavating portion 40 using the wire saw 60 And the steel supporting member 70 is inserted between the struts 71 to support the lower portion of the excavating portion 40 so that both side ends of the supporting member 70 protrude outward from the excavating portion 40, A supporting member inserting step;
A vertical bending step of wrapping the surface of the digging unit 40 with a nonwoven fabric 45 and a waterproofing vinyl 46 and then bending the digging unit 40 in a vertical direction with a metal banding member 47;
A vertical member 92 is connected to the upper portion of the lower connecting member 91 after the lower connecting member 91 connecting the end portions of the supporting members 70 is installed in a direction crossing the supporting member 70 A frame forming step of forming a frame 90 by providing an upper connecting member 93 connecting upper ends of the vertical members 92;
A frame reinforcing step of pulling up the frame 90 in an upward direction and then tilting it to one side and connecting a plurality of auxiliary supporting members 100 in a direction intersecting with the supporting member 70;
And a transporting step of transporting the frame (90).
Footprint fossil discovery method.
The method according to claim 1,
After the frame reinforcing step, the inclined frame 90 is positioned parallel to the ground so that the excavating part 40 is positioned at the center of the frame 90, and then the supporting members 70 at both ends are connected. And a flow preventive step of additionally providing a flow preventive member (80) made of a steel which is in close contact with the excavating part (40) to prevent the flow of the frame (90).
Footprint fossil discovery method.

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